RU2644603C2 - Fluid coupling - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates fluid coupling comprising: socket (14) and plug (12) and is intended for connection of two fluid hoses, wherein plug (12) has neck (18), which is adapted to be inserted into the socket (14), said neck comprising annular groove (62) for engaging locking element (66) in the socket. Locking element (66) comprises a push-button (68), adapted to be actuated in a radial manner from an exterior of the socket (14), two flexible fork arms (70) protruding from the push-button, and being adapted to engage into hub (72) of socket (14), diagonal ramp surfaces (90) on two opposing inner faces being defined on the flexible fork arms, and being adapted to engage around the neck (18) in an area of annular groove (62) on portion of its perimeter. Annular groove (62) is delimited by two opposing and diverging diagonal surfaces (64).

EFFECT: invention simplifies the process of connecting and disconnecting the two liquid hoses.

19 cl, 7 dwg

Description

The invention relates to a fluid coupling with a sleeve and a plug for connecting two fluid hoses according to the restrictive part of paragraph 1 of the claims.

Such couplings are particularly suitable for connecting conductive water hoses with a relatively low pressure of up to 10 bar. In order to connect the plug and the sleeve to each other, the known systems have a sleeve coaxial for this purpose on the sleeve or on the plug, which must be manually removed to connect or disconnect both halves of the coupling, which complicates the process of connection or disconnection.

The basis of the invention is the task of providing a fluid coupling, which allows simplified handling with only one hand both when connecting and when disconnecting both halves of the coupling and which is compatible with most of the common coupling systems.

The solution to this problem stems from the features of paragraph 1 of the claims. Preferred improvements are the subject of the dependent claims.

A significant advantage of the invention compared with the prior art is that to connect both halves of the coupling, they only need to be inserted into each other, and they are fixed independently, while for the disconnection process with the thumb, only the side push button should be pressed.

The invention is further explained by way of example, which is shown in the drawing. The drawing shows:

FIG. 1 is a longitudinal section through the coupling in the open state;

FIG. 2 - coupling in connected and locked state;

FIG. 3 is an enlarged perspective view of a sleeve;

FIG. 4 is a plan view of the sleeve of FIG. 3 without push button;

FIG. 5 - push button outside the sleeve;

FIG. 6 is a top view of a sleeve with a push button in the locked position; and

FIG. 7 - the sleeve of FIG. 6 with a pressed push button in its disconnect position.

As shown in FIG. 1 and 2, the coupling 10 according to the invention consists of two parts, namely a plug 12 and a sleeve 14, which are made in the form of plastic parts.

The plug 12 has a cylindrical body 16, from which a cylindrical neck 18 of smaller diameter protrudes, which serves to enter the sleeve 14. The housing 16 consists of two parts and has a bottom 20 made on the neck 18 with a cylinder 22 protruding from it, which covers the cylinder 24 smaller diameter, from which the connecting pipe 26 with the herringbone profile 28 protrudes coaxially, onto which a liquid hose not shown can be worn. A stepped annular seal 30 is inserted into the cylinder 22, which is pressed against the bottom 20 by the free end of the smaller cylinder 24. A sleeve 32 is put on the larger cylinder 22 for contact with the hand.

The sleeve 14 also consists of several plastic parts and has an essentially cylindrical body 34 with a front receiving cylinder 36 for the neck 18 of the plug 12 and with a rear cylinder 38 with a bottom 40 inserted, from which the connecting pipe 42 with the profile 44 "protrudes "for fluid hose.

On the outer surface of the sleeve 14 in this case also put on a sleeve 46 for contact with the hand. Between the receiving cylinder 36 and the rear cylinder 38 of the housing 34, an annular seal 48 is clamped.

Both in the hollow space of the sleeve 14 and in the hollow space 50 of the plug 12, in each case, an axially displaceable valve stem 52 is arranged with a spherical head 54 formed on it, on the inner concave side of which a clamping spring 56 rests; FIG. 1 and 2 show a compression spring 56 for sleeve 14, while for plug 12 it is not further shown.

In the open state of the clutch 10, both pressure springs 56, which are supported in the corresponding housing 16 or 34, ensure that the spherical head 54 of the valve stem 52 is pressed against the corresponding annular seal 30 or 48, so that there is water in the plug 12 and in the sleeve 14 cannot flow through the corresponding connecting pipe 26 or 42.

If according to FIG. 2, the clutch 10 is closed by inserting the neck 18 of the plug 12 into the sleeve 14, the opposite ends of both valve rods 52 are in contact with each other and move axially against the force of both pressure springs 56. This leads to both spherical heads 54 moving away from their sealing surfaces 58 on the corresponding annular seal 30 or 48, so that the supplied fluid can flow through the connecting pipe 26 or 42.

Next, using FIG. 3-7, the structure and principle of operation of the system for fixing the plug 12 and the sleeve 14 according to the invention are explained. A through hole 60 is selected in the middle of the sleeve 14, into which the mouth 18 of the plug 12 is inserted to connect the fluid hoses. On the outside of the neck 18 there is an annular groove 62 (see also FIGS. 1 and 2), which is bounded by two opposite, diverging inclined surfaces 64, which are inclined to the radial plane at an angle of 45 °. To fix the neck 18 in the hole 60 of the sleeve 14, the one shown in FIG. 5, the locking element 66, which is made of plastic and has a push button 68, from which two flexible fork levers 70 protrude. The fork levers 70 engage with a multi-part socket 72 of the sleeve 14 (see Fig. 3), which is made on the free end face of the sleeve 14 and in FIG. 6 and 7 are shown in black. On the opposite push button 68, the side of the sleeve 14 protrudes in the axial direction of the thrust projection 74, on both sides of which an inclined expanding surface 76 is made. The free ends 78 of both fork arms 70 come into contact with the locking element 66 inserted into the seat 72. If the push button 68 is pressed in order to disconnect the plug 12 from the sleeve 14, then the free ends 78 of the fork arms 70 slide along both expandable surfaces 76 and at the same time the fork arms 70 are opened. It is thereby possible to withdraw the fork arms 70 from engagement with the annular groove 62 of the neck 18, so that it is automatically released by the pressure of both pressure springs 56 and can be pulled out of the hole 60.

If the push button 68 is then released again, then the release spring 92 inserted between it and the stop protrusion 74 of the stop 80, ensures that the locking element 66 with its two fork arms 70 moves back to the non-remote starting position. The specified release spring 92 is worn on the spike 82 protruding from the push button 68. In order to prevent the release spring 92 from pushing the push button 68 out of the socket 72 and thereby from the sleeve 14, two diametrically opposite axial protrusions 84 are made in the socket 72 (see Fig. 4, as well as 6 and 7), which have two diametrically opposite radial end contact surfaces 86, which form a locking step and on which, when the push button 68 is not pressed, i.e. x hooks 88 ends of both fork arms 70.

In particular, from FIG. 5 and 6, that the fork arms 70 on their both opposite inner sides have inclined mortise surfaces 90 that span the neck 18 of plug 12 in the region of its annular groove 62 on the perimeter part. The inclined mortise surface 90 is designed so that they diverge in the axial direction to the plug 12 with the formation of a concave shape. Thus, a fringing guide surface is formed for the insertion neck 18 of the plug 12, which facilitates the insertion of the neck 18 and facilitates the expansion of both fork arms 70.

If the neck 18 according to FIG. 2 is inserted right up to the end stop, with the opposite end surfaces of the sleeve 14 and the plug 12 touching each other, the locking element 66, due to the squeezing spring 92, extends radially to its original position (Fig. 6), so that both fork arms 70 slide into the annular groove 62 of the neck 18. Without pressing the push button 68, both elements 12 and 14 of the coupling cannot be disconnected.

In FIG. 6, it is indicated that the mortise surfaces 90, which are made at the free ends 78 of the fork arms 70, which engage with the annular groove 62 of the neck 18, in the locked state reach at least the middle plane m of the neck 18 or protrude behind it with a slight allowance u, e.g. 1 mm. As a result of this, it is achieved that when a tensile force is exerted on the plug 12, the coupling 10 cannot automatically disconnect.

Claims (21)

1. A fluid coupling comprising a sleeve (14) and a plug (12) for connecting two fluid hoses, the plug (12) having a neck (18) inserted into the sleeve (14) with an annular groove (62) for engaging with the locking element (66), characterized in that the locking element (66) consists of a push button (68) radially actuated from the outside of the sleeve (14), from which two flexible fork arms (70) protrude, which engage with the socket (72) of the sleeve (14) and on their opposite inner sides both have inclined mortise surfaces (90) that span the neck (18) in the region of the annular groove (62) on a part of its perimeter, the annular groove (62) being bounded by two diverging diagonal surfaces (64) . 2. A fluid coupling according to claim 1, characterized in that the inclined mortise surfaces (90) of the fork arms (70) diverge axially towards the plug (12). 3. The fluid coupling according to claim 1 or 2, characterized in that the cut-in surfaces (90) made at the free ends (78) of both fork arms (70) and engaged with the annular groove (62) lock up to the middle plane (m) neck (18) or protrude behind it with a slight allowance (u). 4. A fluid coupling according to claim 1 or 2, characterized in that the free ends (78) of both fork arms (70) are adjacent in each case to one inclined expansion surface (76) of the socket (72) and have hook hooks on their outer side (88), which in the locked state with the push button (68) not pressed, abut against the locking ledge of the socket. 5. A fluid coupling according to claim 3, characterized in that the free ends (78) of both fork arms (70) are adjacent in each case to one inclined expansion surface (76) of the socket (72) and have hook hooks (88) on their outer side ), which in the locked state, when the push button (68) is not pressed, abut against the locking ledge of the socket. 6. A fluid coupling according to claim 4, characterized in that the locking ledge is made by means of two opposite end stop surfaces (86), on which the hook hooks (88) of the fork levers (70) are supported. 7. The fluid coupling according to claim 5, characterized in that the locking step is made by means of two opposite end contact surfaces (86), on which the hook hooks (88) of the fork arms (70) are supported. 8. The fluid coupling according to any one of paragraphs. 1, 2, 5-7, characterized in that a release spring (92) rests on the inside of the push button (68), which in the locked state presses the hook hooks (88) of both fork levers (70) to their locking ledge. 9. A fluid coupling according to claim 3, characterized in that a release spring (92) rests on the inside of the push button (68), which in the locked state presses the hook hooks (88) of both fork levers (70) to their locking ledge. 10. A fluid coupling according to claim 4, characterized in that a release spring (92) rests on the inside of the push button (68), which in the locked state presses the hook hooks (88) of both fork levers (70) to their locking ledge. 11. The fluid coupling according to any one of paragraphs. 1, 2, 5-7, 9, 10, characterized in that both in the hollow space (50) of the plug (12) and the sleeve (14), a valve stem (52) movable in the axial direction against the clamping spring (56) is installed with a spherical head (54) made on it, on the inner concave side of which a clamping spring (56) rests, which in the open state between the sleeve (14) and the plug (12) presses the spherical outer side of the spherical head (54) to the O-ring (30) , 48) in the plug (12) and in the sleeve (14). 12. A fluid coupling according to claim 3, characterized in that both in the hollow space (50) of the plug (12) and the sleeve (14), a valve stem (52) movable in the axial direction against the clamping spring (56) is installed with spherical head (54), on the inner concave side of which rests the clamping spring (56), which in the open state between the sleeve (14) and the plug (12) presses the spherical outer side of the spherical head (54) to the O-ring (30, 48) in the plug (12) and in the sleeve (14). 13. A fluid coupling according to claim 4, characterized in that both in the hollow space (50) of the plug (12) and the sleeve (14), a valve stem (52) movable in the axial direction against the clamping spring (56) is installed with spherical head (54), on the inner concave side of which rests the clamping spring (56), which in the open state between the sleeve (14) and the plug (12) presses the spherical outer side of the spherical head (54) to the O-ring (30, 48) in the plug (12) and in the sleeve (14). 14. A fluid coupling according to claim 8, characterized in that both in the hollow space (50) of the plug (12) and the sleeve (14), a valve stem (52) movable in the axial direction against the clamping spring (56) is installed with spherical head (54), on the inner concave side of which rests the clamping spring (56), which in the open state between the sleeve (14) and the plug (12) presses the spherical outer side of the spherical head (54) to the O-ring (30, 48) in the plug (12) and in the sleeve (14). 15. The fluid coupling according to any one of paragraphs. 1, 2, 5-7, 9, 10, 12-14, characterized in that in the connected state of the plug (12) and the sleeve (14) the opposite ends of both valve rods (52) are in contact with each other when mutual axial movement. 16. The fluid coupling according to claim 3, characterized in that in the connected state of the plug (12) and the sleeve (14) the ends of both valve rods (52) that are opposite to each other are in contact with each other during mutual axial movement. 17. The fluid coupling according to claim 4, characterized in that in the connected state of the plug (12) and the sleeve (14) the ends of both valve rods (52) that are opposite to each other are in contact with each other during mutual axial movement. 18. The fluid coupling according to claim 8, characterized in that in the connected state of the plug (12) and the sleeve (14) the ends of both valve rods (52) that are opposite to each other are in contact with each other during mutual axial movement. 19. The fluid coupling according to claim 11, characterized in that in the connected state of the plug (12) and the sleeve (14) the ends of both valve rods (52) that are opposite to each other are in contact with each other during mutual axial movement.

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